KR100421047B1 - Apparatus for detecting light level in the optical drive and method thereof - Google Patents

Abstract

In the present invention, in detecting the amount of light emitted from a plurality of light sources using a single device, the amount of light detection for each light source is controlled to provide sufficient dynamic range for the maximum amount of emitted light required for each of the plurality of light sources. Apparatus and method.

An apparatus for detecting light quantity according to the present invention, comprising: a light receiving unit for receiving an amount of light emitted from any one of a plurality of light sources; And an amplifying unit for amplifying the light amount received by the light receiving unit according to the selected gain and outputting the amplified light amount as the detected light amount.

Therefore, in detecting the amount of light from each light source, the dynamic range can be sufficiently secured, and efficient APC (Auto Power Control) can be expected.

Description

Apparatus for detecting light level in the optical drive and method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical driver having a plurality of light sources, and more particularly, to a light amount detecting device and a method for detecting the amount of light emitted from a plurality of light sources using a single element.

An optical driver having a plurality of light sources is for driving an optical medium for recording or reproducing at different wavelengths with one optical driver. For example, in order to record or reproduce a disc classified as a CD and a disc classified as a DVD with one optical driver, the optical driver must be provided with a CD light source and a DVD light source, respectively. This is because the wavelengths used for recording or reproducing a disc classified as a CD and the wavelengths used for recording or reproducing a disc classified as a DVD are defined differently.

An optical driver having a plurality of light sources described above, like other conventional optical drivers, may have a lower output when the temperature increases. Therefore, to compensate for this, the APC function of automatically controlling the power of the light source by monitoring the light amount of the light source is provided.

However, currently proposed optical driver with a plurality of light sources is implemented to monitor the amount of light using a single device. That is, the amount of light emitted from the plurality of light sources is respectively detected by using one monitor photodiode (also referred to as MPD or front photodiode (FPD)). Therefore, the sensitivity of the monitor photodiode is set to be kept constant for the plurality of light sources. However, when there is a difference in the maximum amount of emitted light required by the plurality of light sources in the state where the same sensitivity is set for the plurality of light sources as described above, the dynamic range for light quantity detection for all the plurality of light sources cannot be sufficiently secured. Therefore, it is impossible to implement APC within the required optical power.

1 is a diagram showing the relationship between the amount of light required by each light source and the amount of light detected using FPD in an optical driver having a light source for CD and a light source for DVD, respectively. It is about 2 times and the sensitivity of FPD is kept constant with respect to the CD light source and the DVD light source. As can be seen from Fig. 1, when the maximum amount of emitted light is two times different from each other, one side (CD light source) secures enough dynamic range for light quantity detection, while the other side (DVD light source) is necessary for light quantity detection. Only half of the dynamic range is secured.

In order to solve this problem, a method of mounting a monitor photodiode having a sensitivity corresponding to each light source to the optical driver has been proposed, but this has not only hassle of mechanically securing a separate area, but also increases the price of the system. It can also be a factor.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and in detecting the light quantity of a plurality of light sources using a single element, by adjusting the light quantity detection sensitivity according to each light source, the dynamic range for the maximum amount of emitted light required in each of the plurality of light sources It is to provide an apparatus and method for detecting the amount of light that can sufficiently secure the.

Another object of the present invention is to provide an apparatus and method for detecting the amount of light by determining the amplification gain for the amount of light emitted for each light source in detecting the amount of light of a plurality of light sources using a single element.

According to an aspect of the present invention, there is provided an apparatus for detecting an amount of light of a plurality of light sources, the apparatus comprising: a light receiving unit for receiving an amount of light emitted from any one of a plurality of light sources; It is preferable to include an amplifier which amplifies the light amount received by the light receiver according to the selected gain and outputs the amplified light amount as the detected light amount.

The gain selection in the amplifier is preferably controlled by a gain selection signal generated according to the type of optical medium currently used.

Preferably, the amplifying unit selects one of the first gain determined by the variable resistor and one feedback gain resistor and the second gain determined by the variable resistor and the other feedback gain resistor as the amplification gain.

The amplifier selects one of the first gain determined by the first variable resistor, the first fixed resistor, and the feedback gain resistor, and the second gain determined by the second variable resistor, the second fixed resistor, and the feedback gain resistor as an amplification gain. It is desirable to be.

According to another aspect of the present invention, there is provided an apparatus for detecting an amount of light of a plurality of light sources, the apparatus comprising: a light receiving unit for receiving an amount of light emitted from any one of a plurality of light sources; A first amplifier for amplifying the amount of light received by the light receiver with a first predetermined gain and outputting the amplified light amount; A second amplifier for amplifying the amount of light received by the light receiver with a second predetermined gain and outputting the amplified amount of light; It is preferable to include a switch for selecting and outputting one of the amount of light output from each of the first amplification unit and the second amplification unit as the detected amount of light.

The operation of the switch is preferably controlled by a selection signal generated according to the type of optical medium currently used.

Preferably, the first predetermined gain is determined by the first variable resistor and the first feedback gain resistor, and the second predetermined gain is determined by the second variable resistor and the second feedback gain resistor.

According to an aspect of the present invention, there is provided a method of detecting a light quantity of a plurality of light sources, the method comprising: receiving an amount of light emitted from any one of a plurality of light sources; It is preferable to amplify the received light amount according to the gain determined according to the kind of optical medium currently used, and to output the amplified light amount as the detected light amount.

According to another aspect of the present invention, there is provided a method of detecting a quantity of light of a plurality of light sources, the method comprising: receiving an amount of light emitted from any one of a plurality of light sources; Amplifying and outputting the received light amount according to the first predetermined gain; Amplifying and outputting the received light amount according to the second predetermined gain; And selecting one of the amount of light amplified according to the first predetermined gain and the amount of light amplified according to the second predetermined gain and outputting the detected amount of light according to the type of optical medium currently used.

1 is a diagram illustrating a relationship between the optical power provided to each light source and the output of an FPD in an optical driver having a CD light source and a DVD light source, respectively.

2 is an embodiment of a light amount detection device according to the present invention.

3 is another embodiment of a light quantity detecting apparatus according to the present invention.

4 is another embodiment of a light quantity detecting apparatus according to the present invention.

5 is an operation flowchart of a light quantity detecting method according to the present invention.

6 is an exemplary diagram illustrating a relationship between the optical power provided to each light source and the output of the FPD in an optical driver each having a CD light source and a DVD light source.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 illustrates an example of an apparatus for detecting light quantity according to the present invention, which amplifies the amount of light received according to a gain selected by a gain selection signal generated according to a type of optical medium currently used, and amplifies the amount of light amplified. In the case of outputting with the detected amount of light.

2 includes a photodiode PD1, a current / voltage amplifier (hereinafter referred to as an I / V amplifier) 201, and an amplifier 202. As shown in FIG.

The photodiode PD1 functions as a light receiving unit that receives an amount of light emitted from any one of a plurality of light sources (not shown) provided in the light driver. When the optical driver is implemented to drive both the CD disk and the DVD disk, the light source provided in the optical driver is a CD light source and a DVD light source. As described above, when the plurality of light sources are the CD light source and the DVD light source, the photodiode PD1 receives the amount of light emitted from the CD light source or the DVD light source.

The I / V amplifier 201 includes an amplifier AMP1 having resistors R1 and R2 connected to an input terminal receiving a reference voltage Vref and a feedback loop, respectively, to receive light from the photodiode PD1. As a result, the generated current is converted into a voltage and output.

In the amplifier 202, a bias resistor R3 is connected to an input terminal receiving a reference voltage Vref, and two feedback gain resistors G1 and G2 are selectively set in a feedback loop by a gain selection signal applied thereto. The I / V amplifier 201 is connected to the input terminal to which the voltage output from the I / V amplifier 201 is applied, and the feedback gain resistor selected from the feedback gain resistors G1 and G2 is used. It consists of an amplifier AMP2 to which a variable resistor VR1 for determining the amplification gain for the voltage output from the amplifier is connected.

The applied gain selection signal is generated according to the type of optical medium currently used. That is, it is generated based on the correlation between the feedback gain resistors G1 and G2 provided in the amplifier 202 as a result of determining the type of optical medium currently used in the corresponding optical driver. For example, if the type of optical medium currently used requires amplification with a gain determined by the feedback gain resistor G1 and the variable resistor VR1, the amplifier AMP2 may return a feedback loop using the feedback gain resistor G1. A gain select signal is generated to be formed. On the other hand, when amplification is required with the gain determined by the feedback gain resistor G2 and the variable resistor VR1, a gain selection signal is generated such that the amplifier AMP2 forms a feedback loop using the feedback gain resistor G2. .

In order to form the feedback loop in the amplifier AMP2 according to the gain selection signal, a switch SW1 exists between the feedback loop gains G1 and G2 and the output terminal of the amplifier AMP2. The gain selection signal may be generated by a servo controller (not shown) of the optical driver. The variable resistor VR1 is set to a value that satisfies a condition in which a plurality of light sources have little dispersion and have linear characteristics.

Therefore, when the feedback gain resistor G1 is selected by the gain selection signal, the amplifier 202 divides the feedback gain resistor G1 by the variable resistor VR1 (= G1 / VR1) and receives the received light amount. When the feedback gain resistor G2 is selected by the gain selection signal and the feedback gain resistor G2 is selected by the gain selection signal, the feedback gain resistor G2 is divided by the variable resistor VR1 (= G2 / VR1) to obtain an amplification gain. The voltage corresponding to the received light amount is amplified to a predetermined value. The amplified voltage is output with the detected amount of light. The detected amount of light is provided so that it can be used for APC. Therefore, the detected amount of light may be provided to a servo controller not shown.

3 is a view illustrating another example of an apparatus for detecting light quantity according to the present invention, which amplifies the received light amount to a predetermined value according to a gain selected by a gain selection signal generated according to a type of optical medium currently used, and amplifies the amplified light amount. This is the case of outputting with the detected amount of light.

The light amount detecting apparatus shown in FIG. 3 includes a photodiode PD2, an I / V amplifier 301, and an amplifier 302.

Since the photodiode PD2 and the I / V amplifier 301 are configured and operated in the same manner as the photodiode PD1 and the I / V amplifier 201 of FIG. 2, description thereof will be omitted.

The amplifier 302 has a bias resistor R6 connected to an input terminal receiving a reference voltage Vref, one feedback gain resistor G3 connected to a feedback loop, and an I / V amplifier 301. Variable resistors VR2 and VR3 and fixed resistors R4 and R5 which are provided at an input terminal receiving a voltage output from the terminal and are selected to determine an amplification gain together with the feedback gain resistor G3 by a gain selection signal are connected. Consisting of an amplifier AMP3.

The gain selection signal is generated according to the type of optical medium currently used as described in FIG. However, unlike in FIG. 2, the gain selection signal is obtained by determining the type of optical medium currently used in the corresponding optical driver, and the variable resistors VR2 and VR3 and the fixed resistors R4 and R5 included in the amplifier 302. It is generated based on the relationship with

That is, the amplifier AMP3 and the I / V amplifier 301 when the type of optical medium currently used requires amplification with a gain determined by the feedback gain resistor G3, the variable resistor VR2 and the fixed resistor R4. The gain select signal is generated so that the variable resistor VR2 and the fixed resistor R4 are set between the? On the other hand, when amplification is required with the gain determined by the feedback gain resistor G3, the variable resistor VR3 and the fixed resistor R5, the variable resistor VR3 is provided between the amplifier AMP3 and the I / V amplifier 301. And a gain selection signal is generated so that the fixed resistor R5 is set.

According to the gain selection signal, the variable resistor VR2 and the fixed resistor R4 are set between the amplifier AMP3 and the I / V amplifier 301 or the variable resistor VR3 and the fixed resistor R5 are set. For this purpose, a switch SW2 exists between the fixed resistors R4 and R5 and the input terminal of the amplifier AMP3. The variable resistors VR2 and VR3 are set to a value that satisfies a condition in which a corresponding light source among the plurality of light sources is less scattered and has a linear characteristic, and the fixed resistors R4 and R5 are the maximum outputs of different light sources. It sets in consideration of the ratio of light quantity.

Therefore, when the input line in which the variable resistor VR2 and the fixed resistor R4 are set by the gain selection signal is selected, the amplifier 302 returns to the value obtained by adding the variable resistor VR2 and the fixed resistor R4. The voltage corresponding to the amount of light received with the amplification gain obtained by dividing the gain resistor G3 (= G3 / (VR2 + R4)) is amplified to a predetermined value. When the input line having the variable resistor VR3 and the fixed resistor R5 is selected by the gain selection signal, the amplifier 302 returns the feedback gain resistor to the value obtained by adding the variable resistor VR3 and the fixed resistor R5. Amplification gain obtained by dividing (G3) (= G3 / (VR3 + R5)) amplifies the voltage corresponding to the received light amount to a predetermined value. The amplified voltage is output with the detected amount of light. The detected amount of light is provided to be used for APC as in FIG.

4 is a further embodiment of the light amount detecting apparatus according to the present invention, in which a plurality of amplifiers are provided to amplify the amount of light received at a predetermined gain in consideration of a plurality of light sources provided according to the type of optical medium to be used. This is the case where light quantity is detected.

The light amount detecting apparatus shown in FIG. 4 includes a photodiode PD3, an I / V amplifier 401, a first amplifier 402, a second amplifier 403, and a switch SW3.

Since the photodiode PD3 and the I / V amplifier 401 are configured and operated in the same manner as the photodiode PD1 and the I / V amplifier 201 of FIG. 2, description thereof will be omitted.

In the first amplifier 402, a bias resistor R7 is connected to an input terminal receiving a reference voltage Vref, a feedback gain resistor G4 is connected to a feedback loop, and the I / V amplifier 401 is connected. It consists of an amplifier AMP4 having a variable resistor VR4 connected to an input terminal on which a voltage output from the voltage is applied. The variable resistor VR4 is set to a value that satisfies a condition that a corresponding light source has a small dispersion and may have a linear characteristic.

Accordingly, the first amplifier 402 amplifies the voltage output from the I / V amplifier 401 to a predetermined value by an amplification gain obtained by dividing the feedback gain resistor G4 by the variable resistor VR4 (G4 / VR4). Output The amplified voltage output from the first amplifier 402 is transmitted to one terminal of the switch SW3.

On the other hand, in the second amplifier 403, the bias resistor R8 is connected to the input terminal receiving the reference voltage Vref, the feedback gain resistor G5 is connected to the feedback loop, and the I / V amplifier ( It consists of an amplifier AMP5 having a variable resistor VR5 connected to an input terminal receiving a voltage output from the 401. The variable resistor VR5 is set to a value that satisfies a condition that a corresponding light source has a small dispersion and may have a linear characteristic.

Therefore, the second amplifier 403 amplifies the voltage output from the I / V amplifier 401 to a predetermined value with an amplification gain obtained by dividing the feedback gain resistor G5 by the variable resistor VR5 (G5 / VR5). To print. The amplified voltage output from the second amplifier 402 is transmitted to the other terminal of the switch SW3.

The switch SW3 selects and outputs one of a signal output from the first amplifier 402 and a signal output from the second amplifier 403 by a selection signal applied thereto. The signal output at this time is the detected light amount. The selection signal is the same as the gain selection signal and is generated according to the type of optical medium currently used.

5 is an operation flowchart of the light amount detecting method according to the present invention, in which the amplification gain is determined according to the type of optical medium currently used to detect the light amount.

That is, in step 501, a light receiving element such as a photodiode is used to receive the amount of light from a light source from which light is substantially emitted. The amount of light received in operation 502 is converted into a voltage value as in the I / V amplifier 201 of FIG. 2. Next, in step 503, an amplification gain is determined according to the type of optical medium currently used. The voltage value amplified according to the amplification gain determined in step 504 is amplified by a predetermined value, and the voltage value amplified in step 505 is output.

However, in the light quantity detecting method according to the present invention, when the light quantity is received by using one light receiving element, as shown in FIG. Amplifying and outputting the received light amount is performed by the number of light sources included in the optical driver. That is, when two light sources are provided, amplifying and outputting the received light amount according to the gain set for one light source, and amplifying and outputting the received light amount according to the gain set for one other light source. Perform In addition, the method may be implemented by selecting and outputting one of a plurality of light amounts generated through the amplifying and outputting according to the type of optical medium currently used as the detected light quantity.

When the embodiments according to the present invention as described above are applied to an optical driver having a light source for DVD and a light source for CD, respectively, the amount of light (X-axis of FIG. 6) and the amount of detected light (FIG. (Y-axis) has a relationship as shown in FIG. As can be seen in Figure 6 by adjusting the gain (gain) for detecting the amount of light for each light source it is possible to maximize the dynamic range according to the amount of light detection.

According to the present invention described above, in detecting an amount of light emitted from an arbitrary light source using a single element in an optical driver having a plurality of light sources, the amount of light detected is amplified by an amplification gain determined according to the characteristics of each light source. By doing so, it is possible to provide a light amount detection result in which the dynamic range of each light source is sufficiently taken into account, so that an efficient APC can be expected.

The present invention is not limited to the above-described embodiments, and variations of the present invention can be made by those skilled in the art within the spirit of the present invention. Therefore, the scope of the claims in the present invention will not be defined within the scope of the detailed description, but will be limited to the claims below.

Claims (27)

In the apparatus for detecting the amount of light of a plurality of light sources, A light receiving unit that receives the amount of light emitted from the plurality of light sources; A current / voltage amplifier for converting and outputting a current generated according to the amount of light received by the light receiver into a voltage; And an amplifier for amplifying a signal output from the current / voltage amplifier with an amplification gain selected according to a type of optical medium currently used, and outputting the amplified signal as a detected amount of light. delete The method of claim 1, wherein the amplification gain is one of a first gain determined by a variable resistor and one feedback gain resistor of the amplifier and a second gain determined by the variable resistor and the other feedback gain resistor of the amplifier. Light quantity detection device, characterized in that selected. The apparatus of claim 3, wherein the variable resistor is set to a value that satisfies a condition in which the plurality of light sources are less scattered and have linear characteristics, respectively. delete The amplifier of claim 1, wherein the amplification gain includes: a first gain, a second variable resistor, a second fixed resistor, and the feedback gain resistor determined by a first variable resistor, a first fixed resistor, and a feedback gain resistor of the amplifier. And one of the second gains determined by the " The method of claim 6, wherein the first variable resistor, the second variable resistor is set to a value that satisfies a condition that the corresponding light source of the plurality of light sources is less scattered and has a linear characteristic, and the first fixed resistance, 2, the fixed resistance is set in consideration of the ratio of the maximum amount of emitted light of different light sources. In the apparatus for detecting the amount of light of a plurality of light sources, A light receiving unit that receives the amount of light emitted from the plurality of light sources; A current / voltage amplifier for converting and outputting a current generated according to the amount of light received by the light receiver into a voltage; A first amplifier amplifying a signal output from the current / voltage amplifier with a first predetermined gain and outputting the amplified signal; A second amplifier for amplifying a signal output from the current / voltage amplifier with a second predetermined gain and outputting the amplified signal; And a switch for selecting one of the signals output from the first amplifier and the second amplifier according to the type of optical medium currently used, and outputting the detected signal as the detected amount of light. delete 9. The method of claim 8, wherein the first predetermined gain is determined by a first variable resistor and a first feedback gain resistor, and the second predetermined gain is determined by a second variable resistor and a second feedback gain resistor. Light quantity detection device characterized in that. The apparatus of claim 10, wherein the first variable resistor and the second variable resistor are set to a value that satisfies a condition in which a corresponding light source among the plurality of light sources is less scattered and has a linear characteristic. . In the method for detecting the light amount of a plurality of light sources, Receiving an amount of light emitted from the plurality of light sources; Converting a current generated according to the received amount of light into a voltage; And amplifying the light amount converted into the voltage with an amplification gain determined according to the type of optical medium currently used, and outputting the amplified light amount as the detected light amount. In the method for detecting the light amount of a plurality of light sources, Receiving an amount of light emitted from the plurality of light sources; Converting a current generated according to the received amount of light into a voltage; Amplifying and outputting the amount of light converted into the voltage with a first predetermined gain; Amplifying and outputting the amount of light converted into the voltage with a second predetermined gain; And selecting one of the amount of light amplified with the first predetermined gain and the amount of light amplified with the second predetermined gain and outputting the detected amount of light according to the type of optical medium currently used. A light amount detection device for detecting a first light amount from at least a first light source and a second light amount from a second light source, and generating an amplified detection signal representing respective output levels of the first light amount and the second light amount, A light receiving unit receiving at least one of the first light amount and the second light amount and generating a detection signal proportional to the received signal; An amplifier having at least a different first gain and a second gain, the amplifier receiving the detection signal and selectively applying the first gain and the second gain according to a type of recording medium to generate the amplified detection signal; , And the amplifier further includes a first gain adjusting circuit for changing the first gain and a second gain adjusting circuit for changing the second gain. The method of claim 14, wherein the amplifying unit, A first input terminal for receiving the detection signal; An output terminal coupled to the first input terminal and at least a first signal path and a second signal path to output the amplified detection signal; A switch disposed between the first input terminal and the output terminal, the switch having at least a first state and a second state; Wherein the first state is formed as the first signal path between the first input terminal and the output terminal, and the second state is formed as the second signal path between the first input terminal and the output terminal. . The method of claim 15, wherein the amplification unit, And a control input for receiving a type identification signal indicating that one of the first type recording medium and the second type recording medium is to be recorded, And the switch is switched between the first state and the second state based on the type identification signal to select between the first gain and the second gain. 16. The apparatus of claim 15, wherein the first signal path includes at least a first resistor and the first signal path comprises a second resistor different from the first resistor. 18. The method of claim 17, wherein the first resistor is coupled with a first variable resistor and a first fixed resistor, the second resistor is coupled with a second variable resistor and a second fixed resistor, The amplifier includes a first gain adjustment circuit including the first variable resistor; And a second gain adjustment circuit including the second variable resistor. 19. The apparatus of claim 18, wherein the first variable resistor and the second variable resistor change the first gain and the second gain independently of each other. 18. The method of claim 17, wherein the first resistor is coupled with a first variable resistor and a first fixed resistor, the second resistor is coupled with a second variable resistor and a second fixed resistor, And the first variable resistor adjusts the first gain and the second variable resistor adjusts the second gain. 21. The apparatus of claim 20, wherein the first variable resistor and the second variable resistor change the first gain and the second gain independently of each other. 16. The apparatus of claim 15, wherein the amplifier further comprises a second input terminal, the second input terminal is operated in combination with a predetermined reference voltage and the first input terminal is operated in combination with the detection signal, The output is coupled to the detection signal through a first feedback resistor when the switch is in the first state, and the output is coupled to the detection signal through a second feedback resistor when the switch is in the second state. Light quantity detection device characterized by the above-mentioned. 23. The method of claim 22, wherein the first feedback resistor is coupled with a first variable resistor and a first fixed resistor, wherein the first variable resistor adjusts the first gain, And the second feedback resistor is coupled with a second variable resistor and a second fixed resistor, and the second variable resistor adjusts the second gain. 24. The light amount detecting device of claim 23, wherein the first variable resistor and the second variable resistor vary the first gain and the second gain independently of each other. A first light source configured to produce a first amount of light of a first recording power level suitable for optically recording a first type of recording medium and a second recording power level suitable for optically recording a second type of recording medium; A second light source configured to generate a second light amount, and a method for detecting the respective light amounts of at least the first light source and the second light source in an optical recording apparatus having different first recording power levels and second recording power levels, Presetting a first gain for use in detecting the first amount of light of the first light source; Presetting a second gain for use in detecting the second amount of light of the second light source; Determining whether one of the first type recording medium and the second type recording medium is recorded; Detecting at least one of the first light amount and the second light amount; Generating a detection signal proportional to the at least one light quantity detected among the first light quantity and the second light quantity; Selectively applying one of the first gain applied when it is determined that the first type recording medium is recorded and the second gain applied when it is determined that the second type recording medium is recorded, Generate an amplified detection signal, the amplified detection signal having a first dynamic range when the first gain is applied to the detection signal generated from the detection of the first amount of light, the second gain being the first light source Having a second dynamic range when applied to the detection signal generated from the detection of; And And said first gain is predetermined to have a first dynamic range wider than said second dynamic range. 27. The method of claim 25, wherein the first gain is set in advance to maximize the first dynamic range. The method of claim 25, wherein the light amount detection method, Adjusting the first gain such that the characteristic of the amplified detection signal is linearly improved over the first dynamic range; And adjusting the second gain such that the characteristic of the amplified detection signal is linearly improved over the second dynamic range.